Peptide self-assembly processes are central to the etiology of amyloid diseases. Much effort has been devoted to characterizing amyloid structure and the mechanisms of peptide self-assembly leading to amyloid. It has been proposed that aromatic side-chain interactions play a central role in early self-assembly recognition events, but this contention remains somewhat controversial. Recent studies have indicated that in some amyloid peptides, aromatic residues can be exchanged for other hydrophobic residues and these nonaromatic variant peptides still retain competency to form amyloid, although with attenuated kinetics. In an effort to understand the relative contributions of aromatic versus generic hydrophobic interactions, studies to quantify the self-assembly properties of amyloid peptides as a function of increasing hydrophobicity and altered aromatic character have been undertaken. In the present study, the amphipathic (FKFE)(2) peptide has been chosen as a model system. The aromatic phenylalanine residues have been globally replaced with nonaromatic natural residues with lower hydrophobicity (alanine, valine, and leucine) and a nonnatural residue with greater hydrophobicity (cyclohexylalanine). The self-assembly properties of these peptides have been characterized by secondary structure analysis and microscopic analysis of the resulting aggregate structures. These studies confirm that aromatic interactions are not strictly required for amyloid formation and that the nonaromatic, but highly hydrophobic, cyclohexylalanine appears to have unique self-assembly characteristics and enhanced hydrogelation properties. The aromatic phenylalanine-containing peptide displays intriguing solvent- and concentration-dependent polymorphism, suggesting that aromatic interactions, while not essential for self-assembly, may give rise to unique structural features.
Peptide self-assembly leading to cross-β amyloid structures is a widely studied phenomenon because of its role in amyloid pathology and the exploitation of amyloid as a functional biomaterial. The self-assembly process is governed by hydrogen bonding, hydrophobic, aromatic π-π, and electrostatic Coulombic interactions. A role for aromatic π-π interactions in peptide self-assembly leading to amyloid has been proposed, but the relative contributions of π-π versus general hydrophobic interactions in these processes are poorly understood. The Ac-(XKXK)(2)-NH(2) peptide was used to study the contributions of aromatic and hydrophobic interactions to peptide self-assembly. Position X was globally replaced by valine (Val), isoleucine (Ile), phenylalanine (Phe), pentafluorophenylalanine (F(5)-Phe), and cyclohexylalanine (Cha). At low pH, these peptides remain monomeric because of repulsion of charged lysine (Lys) residues. Increasing the solvent ionic strength to shield repulsive charge-charge interactions between protonated Lys residues facilitated cross-β fibril formation. It was generally found that as peptide hydrophobicity increased, the required ionic strength to induce self-assembly decreased. At [NaCl] ranging from 0 to 1000 mM, the Val sequence failed to assemble. Assembly of the Phe sequence commenced at 700 mM NaCl and at 300 mM NaCl for the less hydrophobic Ile variant, even though it displayed a mixture of random coil and β-sheet secondary structures over all NaCl concentrations. β-Sheet formation for F(5)-Phe and Cha sequences was observed at only 20 and 60 mM NaCl, respectively. Whereas self-assembly propensity generally correlated to peptide hydrophobicity and not aromatic character the presence of aromatic amino acids imparted unique properties to fibrils derived from these peptides. Nonaromatic peptides formed fibrils of 3-15 nm in diameter, whereas aromatic peptides formed nanotape or nanoribbon architectures of 3-7 nm widths. In addition, all peptides formed fibrillar hydrogels at sufficient peptide concentrations, but nonaromatic peptides formed weak gels, whereas aromatic peptides formed rigid gels. These findings clarify the influence of aromatic amino acids on peptide self-assembly processes and illuminate design principles for the inclusion of aromatic amino acids in amyloid-derived biomaterials.
Amphipathic peptides composed of alternating polar and nonpolar residues have a strong tendency to self-assemble into one-dimensional, amyloid-like fibril structures. Fibrils derived from peptides of general (XZXZ)(n) sequence in which X is hydrophobic and Z is hydrophilic adopt a putative β-sheet bilayer. The bilayer configuration allows burial of the hydrophobic X side chain groups in the core of the fibril and leaves the polar Z side chains exposed to solvent. This architectural arrangement provides fibrils that maintain high solubility in water and has facilitated the recent exploitation of self-assembled amphipathic peptide fibrils as functional biomaterials. This article is a critical review of the development and application of self-assembling amphipathic peptides with a focus on the fundamental insight these types of peptides provide into peptide self-assembly phenomena.
Amphipathic peptides composed of alternating hydrophobic and hydrophilic amino acids self-assemble into amyloid-inspired, β-sheet nanoribbon fibrils. Herein, we report a new fibril type that is formed from equimolar mixtures of enantiomeric amphipathic peptides (L- and D-(FKFE)(2)). Spectroscopic analysis indicates that these peptides do not self-sort and assemble into enantiomeric fibrils composed of all-l and all-d peptides, but rather coassemble into fibrils that contain alternating L- and D-peptides in a "rippled β-sheet" orientation. Isothermal titration calorimetry indicates an enthalpic advantage for rippled β-sheet coassembly compared to self-sorted β-sheet assembly of enantiomeric peptides.
Stimulus-responsive peptide self-assembly provides a powerful method for controlling self-assembly as a function of environment. The development of a reductive trigger for peptide self-assembly and subsequent hydrogelation is described herein. A self-assembling peptide sequence, Ac-C(FKFE)(2)CG-NH(2), was cyclized via disulfide bonding of the flanking cysteine residues. The macrocyclic form of this peptide enforces a conformational restraint that prevents adoption of the beta-sheet conformation that is required for self-assembly. Upon reduction of this disulfide bond, the peptide relaxes into the preferred beta-sheet conformation, and immediate self-assembly into fibrillar superstructures occurs. At sufficient peptide concentration, self-assembly is accompanied by the formation of rigid, viscoelastic hydrogels.
Amphipathic peptides have an increased propensity to self-assemble into amyloid-like β-sheet fibrils when their primary sequence pattern consists of alternating hydrophobic and hydrophilic amino acids. These fibrils adopt a bilayer architecture composed of two β-sheets laminated to bury the hydrophobic side chains of the β-sheet in the bilayer interior, leaving the hydrophilic side chains exposed at the bilayer surface. In this study, the effects of altering the sequence pattern of amphipathic peptides from strictly alternating hydrophobic/hydrophilic repeats to more complex patterning of hydrophobic and hydrophilic residues on self-assembly of the resulting sequences is reported. Self-assembly of the Ac-(FKFE)2-NH2 peptide was compared to that of four related sequences with varied amino acid sequence patterning: Ac-(FK)2(FE)2-NH2, Ac-KEFFFFKE-NH2, Ac-(KFFE)2-NH2, and Ac-FFKEKEFF-NH2. The Ac-(FKFE)2-NH2 and Ac-(FK)2(FE)2-NH2 peptides effectively self-assembled at high (1.0 mM) and low (0.2 mM) concentrations (pH 3-4) into β-sheet nanoribbons that were 8 and 4 nm wide, respectively. The Ac-KEFFFFKE-NH2 peptide failed to self-assemble at low concentration (pH 3-4), but self-assembled into distinct nanotapes that were ~20 nm in width at high concentration. Ac-(KFFE)2-NH2 and Ac-FFKEKEFF-NH2 failed to self-assemble into fibril/tape-like materials at either high or low concentration at pH 3-4, although Ac-FFKEKEFF-NH2 formed micelle-like aggregates at higher concentrations. At neutral pH, similar self-assembly behavior was observed for each peptide as was observed at acidic pH. An exception was the Ac-FFKEKEFF-NH2 peptide, which formed ~20 nm nanotapes at neutral pH. These results indicate that amino acid sequence patterns exert a profound influence on self-assembly propensity and morphology of the resulting materials even when the overall hydrophobicity or charge of the related peptides are identical. Sequence pattern variation can thus be exploited as a variable in the creation of novel materials composed of self-assembled peptides.
Particle replication in nonwetting templates (PRINT) is a continuous, roll-to-roll, high-resolution molding technology which allows the design and synthesis of precisely defined micro- and nanoparticles. This technology adapts the lithographic techniques from the microelectronics industry and marries these with the roll-to-roll processes from the photographic film industry to enable researchers to have unprecedented control over particle size, shape, chemical composition, cargo, modulus, and surface properties. In addition, PRINT is a GMP-compliant (GMP = good manufacturing practice) platform amenable for particle fabrication on a large scale. Herein, we describe some of our most recent work involving the PRINT technology for application in the biomedical and material sciences.
Nanoparticle (NP) drug loading is one of the key defining characteristics of a NP formulation. However, the effect of NP drug loading on therapeutic efficacy and pharmacokinetics has not been thoroughly evaluated. Herein, we characterized the efficacy, toxicity and pharmacokinetic properties of NP docetaxel formulations that have differential drug loading but are otherwise identical. Particle Replication in Non-wetting Templates (PRINT®), a soft-lithography fabrication technique, was used to formulate NPs with identical size, shape and surface chemistry, but with variable docetaxel loading. The lower weight loading (9%-NP) of docetaxel was found to have a superior pharmacokinetic profile and enhanced efficacy in a murine cancer model when compared to that of a higher docetaxel loading (20%-NP). The 9%-NP docetaxel increased plasma and tumor docetaxel exposure and reduced liver, spleen and lung exposure when compared to that of 20%-NP docetaxel.
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